The Polaris-class Ultra Carrier is a state-of-the-art starship designed by the Mining Guild for the transportation and deployment of various spacecraft, including fighters, shuttles, and medium-sized ships up to 300 meters in length.

The idea for the Polaris-class Ultra Carrier was conceived by Nyx Pine the Royal Representative of the Mining Guild. She was renowned for her innovative approaches to deep-space mining and her vision of integrating advanced technology to optimize resource extraction processes. She proposed the concept of the Polaris Ultra during a critical meeting of the Mining Guild’s executive board in YE 42.

Her primary motivation was the increasing difficulty and cost of mining operations in deep space. Traditional mining vessels were limited by their capacity, and range. The existing fleet was also struggling to keep up with the rapidly growing demand for rare minerals and resources essential for technological advancements.

Relying on the Dragon-class Mobile Refinery for all ore processing, Nyx had allowed for a massive storage capacity to hold large quantities of extracted materials. The carrier's design allowed for continuous mining operations without the need for frequent returns to base, significantly improving efficiency.

To address the challenges of deep-space mining, the Polaris Ultra Carrier was built with a reinforced hull and advanced propulsion systems, enabling it to travel to the farthest reaches of the galaxy. Its self-sustaining life support systems and on-board resource recycling facilities ensured that the crew could remain operational for extended periods.

Understanding the importance of crew welfare, Lady Nyx Pine insisted on incorporating extensive amenities and safety features. The carrier was equipped with comfortable living quarters, recreational areas, and medical facilities. It also featured robust defense mechanisms to protect against space hazards and potential pirate attacks.

The Mining Guild allocated substantial resources to the development of the Carrier. A dedicated team of engineers, scientists, and technicians worked tirelessly for five years to bring Lady Pine’s vision to life. Utilizing the latest advancements in materials science and artificial intelligence, they created a ship that was not only highly functional but also a symbol of technological prowess.

In YE 45, the invitation by the Motoyoshi clan to journey to the Kosuke Sector played a pivotal role in the sequence of events that unfolded in the development of the Polaris-class Ultra Carrier. This prestigious invitation, extended to key figures in the Colonial Initiative Alliance Fleet, necessitated the temporary reallocation of resources and personnel, resulting in an unforeseen delay in the project's timeline. The Motoyoshi clan, close friends of the Mining Guild, known for their influential status and the idea of adventure into unknown space. Consequently, this diversion of critical resources impeded the steady progress of the carrier's development.

Further compounding these delays were the subsequent actions of Astrid Kurosaki, the CEO of the Mining Guild. Kurosaki, a staunch advocate for miner safety, raised significant concerns regarding the operational hazards faced by miners in asteroid belts and uncharted sectors. Her advocacy led to a strategic decision to prioritize the enhancement of safety measures within the guild's operations. This initiative resulted in the accelerated development of the Sentinel-class Control Frigate, a vessel designed specifically to oversee and protect mining operations in perilous environments. The Sentinel-class Control Frigate, equipped with advanced surveillance and defensive systems, and the ability to control robotic bodies, required substantial resources and technological input, further diverting attention and materials from the Polaris-class Ultra Carrier project.

Thus, the convergence of these two significant events—the Motoyoshi clan's invitation and Astrid Kurosaki's safety campaign—led to a cascading effect of delays. The development of the Polaris-class Ultra Carrier, initially envisioned as a cornerstone of the Mining Guild’s Fleet's might, was consequently postponed. This delay underscored the intricate balance of power, safety, and strategic resource allocation in the expansive galactic landscape.

Once the pressing concerns had been addressed, the Mining Guild redirected its focus back to the Polaris-class Ultra Carrier project. The safety enhancements advocated by Astrid Kurosaki were successfully integrated into the Mining Guild's operations, and the strategic diplomatic engagements initiated by the Motoyoshi clan had reached a satisfactory conclusion. With these issues resolved, resources and personnel were reallocated to resume the development of the Ultra Carrier in YE 46.

The first vessel in the Polaris-class, codenamed MG-01 Pioneer, represented a culmination of cutting-edge technology and innovative design. Launched in YE 46.4, the Pioneer made a significant impact upon its debut. The ship's advanced features and operational capabilities demonstrated the Mining Guild's commitment to excellence and technological advancement. The successful launch and subsequent performance of the Pioneer garnered widespread acclaim, marking a pivotal moment in the guild's naval history.

Lady Nyx Pine, a prominent figure within the guild and a key proponent of the Polaris-class project, expressed immense satisfaction with the outcomes. Her endorsement of the MG-01 Pioneer underscored the strategic importance of the Ultra Carrier in bolstering the guild's fleet and expanding its influence in the galaxy. The success of the Pioneer also alleviated the concerns of Astrid Kurosaki, who had initially been cautious about diverting resources from miner safety to the Ultra Carrier project.

With the MG-01 Pioneer operational, the Mining Guild could reduce its dependence on external allies, particularly the New Dusk Conclave. Previously, the guild had relied heavily on the Conclave's Albion-class Carriers to fulfill its strategic and logistical needs. The introduction of the Polaris-class Ultra Carrier marked a significant step toward self-sufficiency and enhanced the guild's ability to project power and protect its interests independently.

The Pioneer’s launch not only exemplified the guild’s engineering prowess but also signaled a new era of autonomy and strength. The successful development of the Polaris-class Ultra Carrier reinforced the guild's position as a formidable force within the galaxy, capable of navigating the complexities of interstellar politics and commerce with newfound confidence and capability.

The Polaris-class Ultra Carrier, exemplified by the MG-01 Pioneer, is a state-of-the-art spacecraft designed to serve as the flagship of the Mining Guild's fleet. This colossal vessel is engineered to provide unparalleled support, defense, and operational capabilities, making it a critical asset in both strategic military and industrial contexts.

The Polaris-class Ultra Carrier is among the largest ships in the galaxy, boasting a length of approximately 20,200 meters. Its vast size allows it to house an extensive array of facilities and personnel. Constructed from advanced composite materials, the hull of the Pioneer is designed to withstand extreme conditions, including heavy firepower and hazardous environmental factors found in deep space and asteroid fields.

The command bridge is equipped with cutting-edge holographic displays and advanced AI systems, allowing for real-time tactical decision-making and fleet coordination. Sophisticated communication arrays enable seamless coordination with other vessels, ensuring unified fleet operations.

The ship features multi-layered energy shielding capable of deflecting or absorbing substantial amounts of damage from various weapon types. The Carrier is armed with an array of high-powered weapons, including laser cannons, railguns, and missile launchers, providing formidable offensive capabilities. Drone Bays: Equipped with multiple drone bays, the ship can deploy swarms of defensive and repair drones to protect itself and support allied vessels.

The carrier has multiple hangar bays that can house a fleet of ships, including fighters, Frigates, Industrial Shuttles, Mobile Refineries, and transport shuttles. This enables rapid deployment and recovery of strike teams and support units. Onboard workshops and repair docks allow for the immediate servicing and refitting of docked ships, ensuring they remain battle-ready.

Comprehensive medical bays and recreational areas ensure the well-being of the crew during long missions. This includes advanced medical equipment and leisure zones to maintain morale.

The Polaris-class Ultra Carrier’s ability to support extensive operations independently reduces the Mining Guild’s reliance on external allies. This enhances strategic flexibility and operational autonomy.

With its formidable offensive and defensive systems, the Carrier can serve as a mobile base of operations, projecting power across vast distances and providing robust support to mining and military operations. The combination of military, logistical, and industrial capabilities makes the Polaris-class Ultra Carrier exceptionally versatile. It can perform a wide range of missions, from frontline combat and fleet coordination to resource extraction and deep-space exploration.

The Carrier serves as a mobile command center for coordinating large-scale fleet operations. Its advanced communication and command systems allow for real-time tactical decision-making and efficient management of fleet movements and engagements.

With its expansive hangar bays, the Carrier can deploy and recover a large number of smaller ships, including fighters, bombers, and shuttles. This capability is crucial for conducting extensive carrier operations, providing air support, and executing rapid strike missions.

The carrier's heavy armament and defensive systems make it an ideal platform for projecting power in contested or hostile regions. It can serve as a deterrent against enemy forces, demonstrating the Mining Guild's military strength.

A sleek vessel, its hull painted in a deep, glossy black that seems to absorb the light around it. Accents of bright crimson run along its contours, highlighting its angular design and the aggressive stance of its structure. Its engines, a vibrant red, leave a trail of fiery energy as it cruises through the starry expanse. The ship’s silhouette is both intimidating and majestic, a testament to the advanced engineering and bold aesthetics of its creators. It’s a ship that commands attention and respect, a true behemoth of the stars.

General notes about ship stats and performance

General notes about armor stats and performance

• Crew: 500,000 operators are recommended, 5,000 are required.
• Maximum Capacity: There are accommodations for 600,000 people.
• About 700,000 people can fit aboard in an emergency, but the ship would be extremely cramped.

• Length: 20,000 meters
• Width: 10,000 meters
• Height: 9,000 meters
• Decks: 1800 decks (5 meters high)

• Continuum Distortion Drive: 10,000 light-years per hour
• Hyperspace Fold Drive: 50 light-years per fold
• Sublight Engines: 0.2c (20% of the speed of light)
• Range: 2 years without resupply/refueling
• Lifespan: 50 years
• Refit Cycle: Every 5 years

Damage Rating (Version 3)

Tier: 14, Medium Capital Ship hull, tier 12 shields

Below are some Compartments of the Polaris-class Ultra Carrier

The Bridge of the Polaris-class Ultra Carrier is the nerve center of the ship, where critical decisions are made, and operations are coordinated. Positioned at strategic locations around the Bridge, navigation consoles display real-time data on the ship's position, trajectory, and course adjustments. Navigation officers monitor celestial maps, coordinate course corrections, and calculate optimal routes for mining expeditions. Banks of communication stations line one side of the Bridge, facilitating constant contact with mining outposts, support vessels, and headquarters. Communication officers relay messages, coordinate with other ships, and manage encrypted channels for secure communications.

Defensive consoles are situated near the rear of the Bridge, overseeing the ship's defensive systems, including shields, point-defense turrets, and countermeasures. Defense officers monitor threat assessments, activate defensive protocols, and coordinate with tactical teams during combat or security incidents. Along the opposite side of the Bridge from the communication stations, engineering consoles provide real-time monitoring and control of propulsion systems, power distribution, and auxiliary systems. Engineering officers optimize energy usage, diagnose system malfunctions, and implement emergency repairs to keep the ship operational.

Positioned at the center of the Bridge, the captain's chair is a commanding seat of authority and responsibility. The captain oversees all ship operations, makes critical decisions, and communicates orders to department heads and crew members. From this vantage point, the captain maintains situational awareness, assesses incoming data, and ensures the safety and efficiency of the mission. Adjacent to the captain's chair is the seat of the Executive Officer (XO), the second-in-command of the ship. The XO assists the captain in managing crew activities, overseeing departments, and handling administrative tasks. Working closely with the captain, the XO provides counsel, implements directives, and ensures effective communication and coordination across the ship.

At the front of the Bridge, a large command console integrates data feeds from navigation, communication, defense, and engineering systems, providing a comprehensive overview of the ship's status and surroundings. From this console, the captain and XO monitor mission progress, evaluate threats, and issue commands to departments and crew members.

Distributed throughout the hull of the carrier, airlocks provide access points for crew members and facilitate EVA (Extra-Vehicular Activity) operations. Airlocks are essential for Crew members performing maintenance tasks or repairs on the exterior of the ship use airlocks to access the hull safely. During mining operations or in response to emergencies, crew members may need to perform spacewalks to inspect equipment, deploy payloads, or conduct repairs outside the frigate.

Airlocks can be used for boarding operations when the carrier approaches other vessels or docking facilities, providing controlled access for crew members and ensuring environmental integrity. While the Carrier itself would have docking facilities, crew members may also utilize smaller shuttlecraft for transportation to and from the frigate, especially during routine operations or when visiting remote mining sites. Shuttles provide flexibility and efficiency for crew mobility, allowing for more frequent trips and reducing the strain on the frigate's docking bays.

The Crew Compartment of the Polaris-class Ultra Carrier provides a comfortable and functional living environment for the crew members, ensuring their physical health, morale, and readiness for the demanding tasks of space exploration and mining operations. It serves as a home away from home, fostering teamwork, camaraderie, and resilience among the crew in the vast expanse of the cosmos. Below is what can be found here.

The Crew Quarters are individual or shared living spaces allocated for the Captain, Executive Officer (XO), and crew members. Each crew member has their own personal space equipped with a sleeping berth, storage lockers, and basic amenities for comfort and privacy. The quarters are designed to optimize space efficiency while providing a comfortable environment for rest and relaxation during off-duty hours.

The Mess Hall is a sprawling space within the Polaris-class Ultra Carrier, designed to accommodate the entire crew of the Carrier, as well as the crew members of ships currently docked in the hangar bays. Inside the Mess Hall, long rows of tables are arranged to provide ample seating for everyone. Crew members can enjoy their meals and take the opportunity to socialize with their colleagues in this welcoming environment. The chefs prepare high-quality, restaurant-grade meals, ensuring that the food not only tastes exceptional but also supports the health and well-being of all who dine there.

The Medical Bay is a fully equipped facility staffed by trained medical personnel, including doctors, nurses, and medics. It provides comprehensive healthcare services, as well as Auto-Docs for supplementary care, as needed.

The Recreation Area offers crew members opportunities for leisure and relaxation during their downtime. It features amenities such as exercise equipment, entertainment systems, gaming consoles, and reading materials to cater to diverse interests and preferences. Crew members can engage in recreational activities, socialize with colleagues, and maintain physical and mental well-being while away from their duties.

The Armory is a secure compartment at the end of the Crew Compartment, housing weapons, ammunition, and security equipment for the protection of the ship and its crew. Accessible only to authorized personnel, the Armory stores a variety of defensive armaments, including firearms, energy weapons, and non-lethal deterrents. It also contains tactical gear, protective equipment, and emergency supplies to enhance the ship's security posture and readiness for potential threats.

The Mining Equipment Storage section of the storage space is dedicated to storing various types of mining equipment used in resource extraction operations. It includes storage racks, compartments, and secure containers for tools, machinery, and specialized mining hardware. The layout is designed to maximize accessibility and organization, with equipment categorized and labeled for quick retrieval and deployment during mining expeditions.

Another portion of the storage space is allocated for storing supplies necessary for sustaining mining operations and supporting the crew onboard the Carrier. This includes consumables such as food, water, medical supplies, spare parts, and maintenance materials. The supplies stockpile is regularly replenished during refueling, and resupply times.

To facilitate the loading and unloading of mining equipment, supplies, and extracted resources, the storage space is equipped with cargo handling equipment such as hoists, cranes, and conveyors. These systems streamline logistics operations, allowing for efficient transfer of cargo between the Carrier, the other ships, mining outposts, and support vessels. Crew members trained in cargo handling procedures oversee these operations to ensure safety and efficiency.

To maintain accurate inventory records and track the movement of equipment, supplies, and resources, the storage space is integrated with inventory management systems. These systems utilize barcode scanners, RFID tags, and computerized databases to monitor stock levels, track usage patterns, and generate replenishment orders as needed. Real-time data feeds enable crew members to manage inventory effectively and anticipate logistical requirements for upcoming missions.

Adjacent to the Mission Storage Areas, these sections of the Cargo Hold are reserved for storing personal belongings, equipment, and supplies belonging to the crew members onboard the Carrier. Crew Storage Areas may include individual storage lockers or compartments assigned to each crew member for storing personal belongings, uniforms, equipment, and other items needed during the mission. Dedicated areas equipped with workbenches, tools, and equipment for crew members to perform routine maintenance tasks, repairs, and modifications on their personal gear or equipment.

Storage space for recreational equipment and amenities, such as sports gear, hobby materials, and entertainment devices, to enhance crew morale and well-being during off-duty hours. The Cargo Hold is equipped with cargo handling equipment, including hoists, cranes, and conveyor systems, to facilitate the loading, unloading, and movement of cargo within the hold. Trained crew members oversee cargo handling operations, ensuring safe and efficient transport of mission-critical equipment and crew belongings.

To preserve the integrity of stored cargo and ensure optimal storage conditions, the Cargo Hold is equipped with environmental control systems. These systems regulate temperature, humidity, and atmospheric conditions within the hold to prevent damage or degradation of sensitive equipment, supplies, and payloads.

The Engineering Section of the Polaris-class Ultra Carrier is a bustling hub of activity, housing essential systems and equipment crucial for the frigate's propulsion, power generation, and overall functionality. Here's an expansion on this vital area:

Located at the rear of the Engineering Section are the Carrier's propulsion systems, including thrusters, maneuvering engines, and navigation controls. Engineers oversee the maintenance, calibration, and operation of these systems to ensure optimal performance and maneuverability during transit and docking maneuvers.

Positioned closer to the middle of the Engineering Section is the Carrier's power generator, which provides the energy necessary to power onboard systems, propulsion systems, life support systems, and other critical subsystems. Engineers monitor power output, fuel consumption, and system efficiency to maintain a reliable power supply throughout the frigate's missions.

The Engineering Section is brightly illuminated to provide optimal visibility for engineers of all species working in the area. Special lighting fixtures are installed to ensure even illumination throughout the section, reducing shadows and enhancing visibility during maintenance and repair tasks. Additionally, holographic displays are integrated into workstations and equipment panels, providing engineers with real-time data, schematics, and diagnostics relevant to the systems or hardware they are working on. These displays offer interactive interfaces and visual aids to streamline troubleshooting, enhance situational awareness, and expedite maintenance procedures.

Surrounding the power generator are various pieces of critical engineering equipment, These are Life Support Systems which are systems responsible for regulating air circulation, temperature control, and atmospheric composition within the Carrier to maintain a habitable environment for crew members. Cooling Systems which are Heat management systems and cooling mechanisms to dissipate excess heat generated by propulsion systems, power generators, and other onboard equipment. Auxiliary Systems which are Backup systems, redundancy measures, and emergency equipment to ensure operational continuity and resilience in the event of system failures or malfunctions. And additional Environmental Controls which are systems for monitoring and controlling environmental factors such as humidity, radiation levels, and electromagnetic interference to safeguard crew health and equipment integrity.

The Hydroponics Bay aboard the Polaris-class Ultra Carrier is a self-contained and sustainable environment designed to cultivate fresh food and plants to supplement the ship's provisions during extended missions in deep space. The Hydroponics Bay utilizes advanced hydroponic Growing Systems, which cultivate plants without soil by delivering nutrients directly to the plant roots suspended in a nutrient-rich water solution. The Hydroponics Bay is equipped with Climate Control systems to regulate temperature, humidity, light levels, and air circulation within the growing environment. Environmental sensors and monitoring systems ensure that growing conditions remain optimal for plant growth and health, with parameters adjusted as needed to mimic natural conditions.

The Hydroponics Bay is capable of growing a diverse range of crops, including leafy greens, herbs, vegetables, fruits, and edible flowers, providing a balanced and nutritious diet for the crew. Crop rotation techniques are employed to maximize yield, minimize nutrient depletion, and prevent the buildup of pests and diseases, ensuring long-term sustainability and productivity. In addition to natural sunlight filtered through specialized windows or skylights, supplementary lighting systems such as LED grow lights are used to provide consistent illumination and promote photosynthesis in the absence of natural light, enabling year-round crop production regardless of external conditions.

Water conservation measures are implemented to minimize water consumption and maximize efficiency within the Hydroponics Bay. Graywater recycling systems collect, filter, and recirculate water from plant trays and irrigation systems, reducing water waste and ensuring sustainable use of onboard resources. The Hydroponics Bay yields a steady supply of fresh, nutritious produce, including leafy greens, tomatoes, cucumbers, peppers, strawberries, and herbs, which are harvested and incorporated into the ship's menu to supplement packaged rations and enhance crew morale and well-being during long-duration missions.

The Carrier’s hangar bays are massive, spacious areas of the ship, integral to its primary function. These expansive sections are meticulously designed to support a wide range of vessels, playing a crucial role in the carrier's versatility and operational effectiveness. The hangar bays are organized into multiple levels, each tailored to accommodate different types of spacecraft and their specific requirements.

The topmost level of the hangar bay is dedicated to landing pads for Stork-class Personnel Transports and similar shuttles. These pads are equipped with advanced landing guidance systems and automated docking protocols to ensure smooth and efficient landings, even in the midst of turbulent conditions. The Stork-class transports are essential for ferrying crew members, miners, and Power Armor between the carrier and other ships or planetary surfaces. The ample space and robust support infrastructure on this level facilitate rapid turnaround times and high-frequency shuttle operations.

The next level is outfitted with docking clamps and magnetic locks designed to secure ships that either lack landing gear or are not intended for traditional landings. This level accommodates vessels such as the Dragon-class Mobile Refineries and the Magpie-class Industrial Shuttles. The Dragon-class refineries are pivotal for processing raw materials extracted during mining operations, converting them into usable resources directly within the hangar bay. The Magpie-class shuttles, on the other hand, are industrial workhorses used for transporting heavy bulk materials. The advanced docking mechanisms on this level ensure that these ships remain securely fastened, providing stability during onboard processing and maintenance activities.

Deep within the hangar bay, dedicated spaces are reserved for Sentinel-class Control Frigates. These frigates are critical for the carrier's defensive and operational support roles, providing command and control functions, electronic warfare capabilities, and additional firepower. The storage areas for these frigates are designed with extensive support infrastructure, including maintenance bays, refueling stations, and quick-launch systems. The layout allows for the rapid deployment of Sentinel-class frigates in response to emerging threats or mission requirements, ensuring the carrier can maintain a robust defensive posture and support fleet operations effectively.

The hangar bays are equipped with an array of automated systems and robotics to assist with ship handling, repairs, and logistics. Drones and robotic arms facilitate quick refueling, rearming, and minor repairs, reducing the turnaround time for all docked vessels. Integrated workshops and repair bays provide comprehensive maintenance capabilities, allowing for both routine servicing and emergency repairs. These facilities are staffed by highly skilled technicians and are stocked with spare parts and advanced diagnostic equipment. Advanced environmental control systems maintain optimal conditions within the hangar bays, including atmospheric regulation, temperature control, and contamination prevention. This ensures a safe and efficient working environment for personnel and the protection of sensitive equipment. The hangar design allows for flexible space utilization, capable of adapting to various mission profiles. Whether the carrier is engaged in combat operations, or industrial activities, the hangar bays can be reconfigured to meet the specific needs of the task at hand.

On the exterior of the Polaris-class Ultra Carrier, specifically beneath the hangar bay area, are specialized clamps designed for a critical and unique purpose: facilitating the transport of Oasis-class Mobile Settlements. These clamps are a key feature that enhances the carrier’s versatility and logistical capabilities, allowing it to support large-scale colonization and settlement efforts.

The specialized clamps located under the hangar bay area are robust and intricately engineered to handle the considerable size and weight of the Oasis-class Mobile Settlements. These settlements are essentially self-contained, mobile living environments that can house large populations and provide all necessary amenities for long-term habitation.

The clamps are constructed from high-strength alloys and composite materials, ensuring they can securely hold the massive settlements even under the stresses of space travel and gravitational forces encountered during planetary landings and takeoffs. Equipped with advanced locking mechanisms, these clamps provide a precise and secure grip on the settlements. The locking systems use a combination of mechanical latches and magnetic locks, ensuring that the mobile settlements remain firmly attached to the carrier during transport. Integrated shock absorption systems help to stabilize the attached settlements, mitigating the effects of vibrations and impacts. This is crucial for protecting the integrity of the mobile settlements and ensuring the comfort and safety of their inhabitants during transit. The clamps feature automated systems for docking and release, allowing for efficient attachment and detachment of the mobile settlements. These systems are controlled from the carrier’s command bridge, enabling quick deployment or retrieval as mission requirements dictate.

The primary function of these clamps is to facilitate the transport of Oasis-class Mobile Settlements between different locations. This capability is essential for supporting colonization efforts, enabling the rapid deployment of habitable environments to new or developing regions. The clamps allow the carrier to transport the mobile settlements to planetary surfaces. Once in orbit, the carrier can maneuver to a suitable deployment position and release the settlements, which can then descend to the surface using their own thrusters or guided landing systems.

In addition to colonization, the ability to transport mobile settlements is invaluable for emergency relief operations. The carrier can quickly deliver these self-sustaining habitats to disaster-stricken areas, providing immediate shelter and support for displaced populations. The mobile settlements can also serve as temporary industrial or research outposts. By transporting these settlements, the carrier supports the expansion of the Mining Guild’s industrial activities and scientific research in remote or newly discovered regions.

The Armored Hull and Hull Integrated Systems of the Polaris-class Ultra Carrier represent a robust and resilient structural framework designed to ensure the safety, durability, and functionality of the ship in the harsh and unforgiving environment of deep space.

Structural Integrity of the Armored Hull forms the outer shell of the Carrier, providing protection against micro-meteoroid impacts, space debris, radiation, and other hazards encountered during space travel and mining operations. Constructed from reinforced alloys and composite materials, the hull is engineered to withstand extreme pressures, temperatures, and environmental stresses encountered in space. The Armored Hull incorporates defensive systems and measures to enhance the Carrier's survivability and resilience in combat situations or hostile environments. This includes energy shields, armor plating, and reactive armor modules designed to deflect or absorb incoming projectiles, laser fire, and other forms of hostile aggression.

The Armored Hull is designed with redundancy and safety features to mitigate the risk of catastrophic failure and ensure the survivability of the ship and its crew in the event of system malfunctions, accidents, or emergencies. This may include compartmentalization, emergency bulkheads, and redundant systems for life support, propulsion, and power generation. The Hull Integrated Systems encompass a range of interconnected subsystems and components integrated directly into the structural framework of the Carrier, optimizing space utilization, efficiency, and performance. Load-bearing structures, trusses, and braces integrated into the hull to distribute weight, support equipment, and withstand external forces encountered during acceleration, deceleration, and maneuvering maneuvers.

The metal material composition of the hull of the Polaris-class Ultra Carrier is a combination of advanced alloys and composite materials specifically engineered to withstand the rigors of space travel, mining operations, and potential encounters with hazards such as micro-meteoroids and space debris. This Material is called Ultrite, a material from Draco Eridanus System first planet from the sun, and formerly a rogue planet.

Ultrite’s composite makeup is made up of equal parts Titanium, Steel, Tungsten, Chromium, iridium. During their molten origins, the electromagnetic field crushed the molten alloy so constricted. This began to affect the alloy at the molecular level since heat is being used, this made the molecules separate, and by the force of the crush, the molecules began forming back together, but not to their original positions but new ones, and to new different molecules that stabilized into something new.

As this happened at the molecular level, at the normal level, the heat and the pressure cause the alloy to begin to visibly merge, spreading and filling the metal changing as they merged. The metal with the addition of Chromium causes the finished new metal to be silver and reflective which is similar to the state of stainless steel. Reactive Armor Modules composed of specialized metal alloys are integrated into the hull to provide additional protection against kinetic energy penetrators and shaped charges, deflecting or disrupting incoming projectiles before they can breach the hull.

The computers and electronics aboard the Polaris-class Ultra Carrier represent a sophisticated array of systems and components essential for navigation, communication, automation, and mission control. Here's an overview of the key computer and electronic systems:

AI systems augment crew capabilities by providing advanced data analysis, decision support, and automation capabilities. AI algorithms optimize operational efficiency, predict system performance, and assist with mission planning and execution, enhancing overall mission success and crew productivity. This is done by using a sophisticated computer network interconnects various systems, subsystems, and components throughout the Carrier. This network facilitates data exchange, information sharing, and system integration, enabling seamless operation and coordination of onboard systems.

Automation and control systems manage and regulate critical functions and processes aboard the Carrier. This includes propulsion control, life support management, power distribution, environmental control, and safety monitoring systems to ensure operational efficiency and crew safety. Advanced navigation systems provide precise positioning, course plotting, and trajectory calculations for the ship. This includes inertial navigation systems (INS), star trackers, and celestial navigation aids to ensure accurate and reliable navigation in deep space.

Robust cybersecurity measures protect the Carrier's computer systems and electronic infrastructure from cyber threats, hacking attempts, and information breaches. This includes encryption protocols, firewalls, intrusion detection systems, and regular security audits to safeguard sensitive data and ensure system integrity. The AI work in tandem with the Cyberwarfare Suite, a specialized suite of cyberwarfare systems installed on the Carrier. They augment the suite's capabilities by executing coordinated cyber-attacks, launching malware payloads, and conducting electronic warfare operations against enemy vessels, particularly pirate ships and hostile factions.

The AI utilize Strategic Distraction Tactics to divert enemy attention and resources away from the Carrier's and by that extension the Mining Guild's primary objectives. They may generate false sensor readings, spoof communications, or create simulated threats to deceive and confuse enemy crews, forcing them to allocate resources to deal with perceived threats, thereby weakening their defensive posture and allowing the frigate to gain a tactical advantage.

Integrated within the command center are advanced communication systems capable of establishing and maintaining long-range communication links with mining outposts, support vessels, and headquarters. These communication systems include encryption protocols which are secure encryption protocols safeguard communication channels, protecting sensitive data and ensuring the confidentiality and integrity of communications exchanged between the Carrier and external entities.

Surrounding the ship are arrays of advanced sensors and scanners strategically positioned to monitor the surrounding space, celestial bodies, and mining operations. These sensory arrays include High-resolution lidar (light detection and ranging) and radar systems scan the environment, providing detailed maps of asteroids, comets, and other celestial objects, as well as detecting potential hazards and obstacles. Optical telescopes and infrared sensors capture images and spectral data of distant objects, allowing operators to study geological formations, identify resource-rich locations, and monitor celestial phenomena relevant to mining operations.

High-frequency satellite uplinks enable real-time data transmission and remote control capabilities, ensuring seamless communication between the carrier and remote mining facilities or command centers. The computer systems houses powerful data processing units and supercomputers tasked with analyzing vast amounts of data collected from sensors, drones, and robotic bodies. These data processing units include:

Advanced AI algorithms analyze sensor data, identify patterns, and make predictive assessments to optimize mining operations, detect anomalies, and anticipate potential threats or opportunities. User-friendly data visualization tools and interfaces display real-time data streams, 3D maps, and interactive dashboards, enabling operators to monitor mining activities, assess resource availability, and make informed decisions. SachiTech Tech-Scanner An additional piece of technology that could be used to help how technology works.

To ensure the safety of the crew and protect against the hazards of space exposure, the windows of the ship utilizes advanced projection screens that display real-time images and footage captured by sensors positioned around the exterior of the ship. These screens offer high-definition views of mining operations, celestial bodies, and space phenomena, providing crew members with a comprehensive understanding of their surroundings.

The emergency systems of the Polaris-class Ultra Carrier are designed to mitigate risks, ensure crew safety, and maintain operational readiness in the face of unforeseen challenges and emergencies, accidents, or unexpected contingencies encountered during missions in deep space. By incorporating redundancy, automation, and comprehensive contingency planning, the Carrier is well-prepared to handle emergencies and protect the lives and well-being of its crew members.

The Carrier is equipped with redundant power generation systems and emergency backup batteries to provide essential electrical power in the event of primary power system failures or disruptions. Emergency power sources are strategically distributed throughout the ship to maintain critical systems, life support, and communications during power outages.

Life support systems feature redundancy and backup capabilities to sustain crew members in the event of environmental control failures, life support malfunctions, or atmospheric emergencies. Backup oxygen supplies, CO2 scrubbers, and temperature regulation systems ensure breathable air, comfortable temperatures, and safe living conditions for crew members during emergencies.

The Carrier has established emergency evacuation procedures and protocols to facilitate rapid and orderly evacuation of crew members in the event of hull breaches, critical system failures, or imminent threats to the ship's integrity. Escape pods, emergency airlocks, and evacuation routes are clearly marked and readily accessible to crew members in all areas of the ship.

Advanced hull integrity monitoring systems continuously monitor the structural integrity of the Carrier's hull, bulkheads, and compartments, detecting signs of damage, breaches, or stress fractures that could compromise the ship's safety. Real-time alerts and alarms notify crew members and command personnel of critical issues requiring immediate attention or evacuation.

Automated fire suppression systems are installed throughout the Carrier to detect and extinguish fires in various compartments, equipment bays, and critical systems. These systems utilize inert gases, foam, or water mist to suppress fires quickly and prevent them from spreading, minimizing damage to the ship and ensuring crew safety.

The Carrier is equipped with medical facilities, sickbays, and first aid stations staffed by trained medical personnel to provide emergency medical care, triage, and treatment for injured or incapacitated crew members. Medical supplies, trauma kits, and diagnostic equipment are readily available to address medical emergencies and injuries.

Dedicated emergency communication systems enable crew members to signal distress, request assistance, and coordinate emergency response efforts with external parties, such as nearby ships, rescue teams, or command centers. These systems include distress beacons, emergency radio channels, and encrypted communication protocols to ensure reliable communication in crisis situations.

Trained damage control teams are assigned specific roles and responsibilities for responding to emergencies, conducting damage assessments, and implementing corrective actions to stabilize the ship and mitigate further damage. Regular drills, training exercises, and simulations prepare crew members to respond effectively to a wide range of emergency scenarios.

The life support systems of the Polaris-class Ultra Carrier are integral to sustaining the health, comfort, and well-being of the crew during long-duration missions in deep space. These systems are designed to provide a habitable and safe environment by regulating atmospheric conditions, temperature, humidity, and air quality within the confines of the ship.

Life support systems maintain a stable and breathable atmosphere within the ship by regulating the composition of gases, particularly oxygen and carbon dioxide. Oxygen generators produce oxygen through electrolysis or chemical reactions, while carbon dioxide scrubbers remove excess CO2 from the air to prevent buildup and maintain safe levels of oxygen for crew respiration. Ducts, vents, and thermal management systems integrated into the hull to regulate temperature, dissipate heat generated by onboard systems, and maintain optimal environmental conditions for crew comfort and equipment operation.

Sophisticated Ducts, vents, and thermal management systems integrated into the hull to regulate temperature, dissipate heat generated by onboard systems, and maintain optimal environmental conditions for crew comfort and equipment operation. Thermal insulation materials and energy-efficient heating/cooling units ensure thermal stability and energy conservation, minimizing energy consumption while maximizing crew comfort. Humidity levels are carefully controlled to prevent excessive dryness or moisture buildup within the ship. Humidifiers and dehumidifiers maintain optimal humidity levels, preventing discomfort, condensation, and moisture-related issues that could affect equipment performance and crew health.

Ventilation systems ensure the circulation of fresh air throughout the ship, preventing stagnation and maintaining air quality. Air filters remove contaminants, dust particles, and airborne pathogens, while fans and ducts distribute clean air to all compartments, ensuring uniform ventilation and circulation. Backup oxygen supplies are available in case of primary system failures or emergencies, providing a reserve of breathable air to sustain crew members until normal operations can be restored. Emergency oxygen masks, tanks, and distribution systems are strategically located throughout the ship for rapid deployment in crisis situations.

Comprehensive environmental monitoring systems continuously monitor atmospheric conditions, temperature, humidity, and air quality throughout the ship. Sensors and detectors alert crew members to any deviations from normal parameters, enabling prompt intervention and corrective action to maintain optimal life support conditions. Life support systems are integrated with emergency systems and protocols to ensure continuity of operations and crew safety during emergencies. Backup power sources, redundant components, and fail-safe mechanisms are in place to maintain life support functionality in the event of power outages, system malfunctions, or other critical failures.

Channels or tubes through which a thin film of nutrient solution flows, providing essential nutrients to plant roots while promoting efficient nutrient uptake and oxygenation. Automated irrigation systems that deliver precise amounts of nutrient solution directly to plant roots, ensuring optimal hydration and nutrient absorption without water wastage. Mist or fog systems that suspend plant roots in the air and deliver nutrient-rich mist, promoting rapid growth and efficient nutrient absorption while minimizing water usage.

The power systems of the Carrier are crucial for providing the necessary electrical energy to support various onboard systems, equipment, and operations throughout the duration of missions in deep space. These systems are designed with redundancy, resilience, and reliability in mind, leveraging advanced technologies and fail-safe mechanisms to ensure continuous power supply and operational readiness in the demanding and unpredictable environment of deep space.

By incorporating multiple layers of redundancy and backup systems, the Carrier is capable of withstanding power-related challenges and maintaining mission-critical functionality under adverse conditions.

The primary source of power for the Carrier is fusion reactors, which generate energy through controlled fusion reactions. Fusion reactors harness the immense energy released when Plasma and ions fuse together, producing high-temperature plasma that is converted into electrical energy through electromagnetic induction or other means. Electrical energy generated by fusion reactors is distributed throughout the ship via a sophisticated power distribution grid. This grid consists of cables, conduits, and distribution panels that route electrical power to various subsystems, compartments, and equipment bays as needed.

Redundant fusion reactors serve as backup power sources to provide additional resilience and reliability in case of primary reactor failures or emergencies. These backup reactors are activated automatically or manually upon detection of primary system anomalies, ensuring continuous power supply and operational readiness. Emergency backup batteries are installed throughout the ship to provide short-term power during transient power outages, reactor startups, or critical system reconfigurations. These batteries are charged continuously and automatically engage during power disruptions to maintain essential systems and prevent mission-critical failures.

Advanced power management systems optimize power distribution, load balancing, and energy efficiency across the ship's electrical grid. These systems monitor power usage, prioritize critical systems, and dynamically adjust power allocation to meet changing operational demands while minimizing energy wastage. Critical power distribution components, such as circuit breakers, transformers, and switching devices, are duplicated or triplicated to ensure redundancy and fault tolerance. Redundant circuits and power pathways are established to bypass damaged or malfunctioning components, preserving power flow and system functionality in the event of localized failures.

Automated failover mechanisms detect and respond to power system anomalies, switching between primary and redundant power sources seamlessly to maintain continuous operation without interruption. These failover mechanisms utilize sensors, control algorithms, and predictive analytics to anticipate and mitigate potential failures before they occur, ensuring maximum uptime and reliability of power systems.

The propulsion systems of the Polaris-class Ultra Carrier are essential for maneuvering, navigation, and traversing vast distances in the depths of space. These systems combine advanced sublight thrusters with warp drive technology to provide efficient, reliable, and versatile means of propulsion for maneuvering within star systems and traversing the vast distances of interstellar space. By leveraging both sublight and FTL propulsion systems, the carrier is capable of undertaking long-range exploration missions, conducting mining operations, and responding to emergencies or threats in the far reaches of the galaxy.

Warp navigation systems calculate and plot safe trajectories for FTL jumps, taking into account gravitational fields, celestial bodies, and spatial anomalies that could affect the stability and safety of the warp bubble. These systems ensure accurate and reliable navigation during FTL travel, minimizing the risk of collisions, misjumps, or spatial distortions that could compromise the frigate's safety and integrity.

The shield systems of the Polaris-class Ultra Carrier are critical defensive components designed to protect the ship from various threats, including enemy weapons fire, micrometeoroids, radiation, and other hazards encountered during space travel and combat. Thus it ensures the safety and survivability of the ship and its crew in the challenging and perilous environment of deep space.

The Carrier is equipped with deflector shields that create a protective energy barrier around the ship, deflecting or absorbing incoming projectiles, energy weapons, and debris. Deflector shields operate by projecting a coherent energy field that intercepts and disperses hostile threats before they can impact the ship's hull.

Deflector shields are adjustable in strength and configuration, allowing the crew to modulate shield levels to match the intensity of incoming attacks or environmental hazards. Shields can be concentrated in specific areas of the ship to provide enhanced protection against targeted threats or evenly distributed to provide comprehensive coverage across the entire hull.

Shield generators are the primary components responsible for generating and sustaining the deflector shields of the carrier. These generators harness energy from the ship's power systems, such as fusion reactors or auxiliary power sources, to generate the electromagnetic fields that form the shield barrier.

Shield generators are strategically positioned throughout the ship to ensure uniform coverage and redundancy in shield deployment. Multiple generator arrays may be installed to provide overlapping shield coverage and compensate for localized shield failures or damage.

Shield modulation and frequency tuning capabilities allow the carrier to adjust the properties and characteristics of its deflector shields to counter specific types of threats or weapon systems. By modulating shield frequencies, the carrier can adapt its defenses to penetrate enemy shields, disrupt energy-based attacks, or counteract electronic warfare tactics.

Shield frequency tuning also enables the frigate to counteract resonance-based weapons, such as disruptors or harmonic disruptors, by adjusting shield frequencies to negate or minimize their effects.

Energy management and recharge systems regulate the power distribution and allocation for shield operations, ensuring optimal performance and efficiency of shield systems during combat engagements. These systems prioritize shield power over other non-essential systems, dynamically adjusting energy flow to reinforce shield barriers and maintain defensive integrity.

Recharge systems rapidly replenish depleted shield energy reserves during lulls in combat or downtime, allowing the Carrier to recover and restore shield strength before resuming defensive operations or engaging in further combat encounters.

Emergency shield protocols are activated automatically or manually in response to imminent threats or critical system failures. These protocols maximize shield strength and resilience by diverting additional power to shield generators, reinforcing shield barriers, and implementing evasive maneuvers to minimize exposure to hostile fire.

Emergency shield protocols may also trigger defensive maneuvers, such as evasive maneuvers or rapid course changes, to avoid incoming threats or projectiles while shield systems are reinforced or repaired.

The weapons systems of the Polaris-class Ultra Carrier are designed for defending the ship against various threats, including hostile vessels, pirates, and other adversaries encountered during space missions. These systems encompass a diverse array of offensive and defensive armaments, including main weapons, secondary weapons, tertiary weapons, fourth weapons, and point defense weapons. By incorporating a mix of energy-based, kinetic, and missile-based weapons, the Carrier is capable of adapting to various combat scenarios and effectively defending itself and its crew against hostile adversaries.

Albatross Anti Starship Laser Array:(Tier 11) Albatross Anti Starship Laser Array are primary energy-based weapons fixed emplacements across the Carrier's hull at the front. These beams project streams of high-energy particles at near-light speeds, capable of penetrating enemy shields and armor with devastating effect. Particle beams provide long-range firepower and precision targeting, making them effective against enemy capital ships and larger targets. Numbered in 1

Missile Launchers:(Tier 10) Missile launchers are secondary weapons systems that launch guided missiles or torpedoes at enemy targets. These missiles can be equipped with various warhead payloads, including high-explosive, anti-ship, anti-fighter, or electronic warfare payloads, allowing for flexible engagement options depending on the tactical situation. numbered in 100

Plasma Cannons:(Tier 11) Plasma cannons are heavy energy weapons that discharge concentrated plasma bolts at enemy targets, causing widespread thermal damage upon impact. Plasma cannons are effective against shielded targets and armored vessels, providing high burst damage and area-of-effect capabilities. 30 in number

Gauss Cannons:(Tier 11) Gauss cannons are advanced electromagnetic weapons that accelerate ferromagnetic projectiles to hypervelocity speeds, delivering kinetic impacts with tremendous force. Gauss cannons excel at penetrating enemy armor and shields, inflicting significant damage to critical systems and subsystems. 20 in number

Origin Point Defense Weapons:(Tier 9) are automated point defense systems equipped with rapid-fire energy-based weapons designed to intercept and destroy incoming missiles, torpedoes, and enemy fighters at close range. CIWS provide last-ditch defense against fast-moving threats, ensuring the frigate's protection against saturation attacks and swarm tactics. 1000 in number

The Vehicle Complement of the Polaris-class Ultra carrier consists of a diverse array of vehicles and auxiliary craft essential for supporting the Carriers's operations, exploration missions, and tactical deployments in space and planetary environments. From transportation and exploration to mining and combat support, these vehicles and auxiliary craft contribute to the frigate's effectiveness and success in fulfilling its duties across the vast expanse of space.

The Vehicle Complement includes a variety of shuttles and utility craft for personnel transportation, cargo logistics, and maintenance operations. These craft are used for intra-system travel, orbital maneuvers, and docking procedures, providing essential support for crew mobility and mission logistics.

The Carrier is equipped with Stork-class Transport Ships capable of ferrying personnel, supplies, and equipment between the frigate and planetary surfaces or remote outposts. Stork transports feature versatile design configurations, including cargo transport, troop transport, and medical evacuation capabilities, enabling them to support a wide range of mission requirements.

The Vehicle Complement includes a fleet of mining drones and robotic bodies used for sucking, Escavations, and resource extraction operations. These drones are remotely controlled by operators aboard the frigate or autonomously guided by AI systems, allowing for efficient and precise mining operations on planetary surfaces, asteroid fields, or other celestial bodies.

The Vehicle Complement includes Repair and Maintenance Drones equipped with tools, manipulators, and diagnostic equipment for conducting routine maintenance, repairs, and servicing of the frigate's systems and subsystems. These drones assist engineering crews in troubleshooting and resolving technical issues, ensuring operational readiness and system reliability.

Fighter Squadrons: The frigate deploys fighter squadrons consisting of 800 agile Mozu-Class Starfighter and Mōkin-Class Patrol Craft.

It is Supplemented by 900 Starfighters equipped with advanced weapons and defensive systems for space combat and defensive operations. These fighters are tasked with escort missions, interception patrols, and tactical engagements, enhancing the frigate's defensive capabilities and combat readiness in hostile environments.

The Carrier is equipped with a complement of exploration probes and unmanned spacecraft designed for scientific research, reconnaissance, and surveying missions. These probes are equipped with sensors, cameras, and scientific instruments to gather data on planetary geology, atmospheric conditions, and astronomical phenomena, contributing to the frigate's exploration and discovery objectives. Mining Probe The main purpose of the Probes is to mark locations that were detected to have rich deposits of multiple materials depending on what the Searchers are looking for.

Charaa created this article on 2024/06/02 22:45.

This article was approved by Andrew on 2024/06/12.¹⁾